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// Copyright 2010 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Package suffixarray implements substring search in logarithmic time using
// an in-memory suffix array.
//
// Example use:
//
// // create index for some data
// index := suffixarray.New(data)
//
// // lookup byte slice s
// offsets1 := index.Lookup(s, -1) // the list of all indices where s occurs in data
// offsets2 := index.Lookup(s, 3) // the list of at most 3 indices where s occurs in data
//
package suffixarray
import (
"bytes"
"encoding/binary"
"exp/regexp"
"io"
"os"
"sort"
)
// Index implements a suffix array for fast substring search.
type Index struct {
data []byte
sa []int32 // suffix array for data; len(sa) == len(data)
}
// New creates a new Index for data.
// Index creation time is O(N*log(N)) for N = len(data).
func New(data []byte) *Index {
return &Index{data, qsufsort(data)}
}
// Read reads the index from r into x; x must not be nil.
func (x *Index) Read(r io.Reader) os.Error {
var n int32
if err := binary.Read(r, binary.LittleEndian, &n); err != nil {
return err
}
if 2*n < int32(cap(x.data)) || int32(cap(x.data)) < n {
// new data is significantly smaller or larger then
// existing buffers - allocate new ones
x.data = make([]byte, n)
x.sa = make([]int32, n)
} else {
// re-use existing buffers
x.data = x.data[0:n]
x.sa = x.sa[0:n]
}
if err := binary.Read(r, binary.LittleEndian, x.data); err != nil {
return err
}
if err := binary.Read(r, binary.LittleEndian, x.sa); err != nil {
return err
}
return nil
}
// Write writes the index x to w.
func (x *Index) Write(w io.Writer) os.Error {
n := int32(len(x.data))
if err := binary.Write(w, binary.LittleEndian, n); err != nil {
return err
}
if err := binary.Write(w, binary.LittleEndian, x.data); err != nil {
return err
}
if err := binary.Write(w, binary.LittleEndian, x.sa); err != nil {
return err
}
return nil
}
// Bytes returns the data over which the index was created.
// It must not be modified.
//
func (x *Index) Bytes() []byte {
return x.data
}
func (x *Index) at(i int) []byte {
return x.data[x.sa[i]:]
}
// lookupAll returns a slice into the matching region of the index.
// The runtime is O(log(N)*len(s)).
func (x *Index) lookupAll(s []byte) []int32 {
// find matching suffix index range [i:j]
// find the first index where s would be the prefix
i := sort.Search(len(x.sa), func(i int) bool { return bytes.Compare(x.at(i), s) >= 0 })
// starting at i, find the first index at which s is not a prefix
j := i + sort.Search(len(x.sa)-i, func(j int) bool { return !bytes.HasPrefix(x.at(j+i), s) })
return x.sa[i:j]
}
// Lookup returns an unsorted list of at most n indices where the byte string s
// occurs in the indexed data. If n < 0, all occurrences are returned.
// The result is nil if s is empty, s is not found, or n == 0.
// Lookup time is O(log(N)*len(s) + len(result)) where N is the
// size of the indexed data.
//
func (x *Index) Lookup(s []byte, n int) (result []int) {
if len(s) > 0 && n != 0 {
matches := x.lookupAll(s)
if n < 0 || len(matches) < n {
n = len(matches)
}
// 0 <= n <= len(matches)
if n > 0 {
result = make([]int, n)
for i, x := range matches[0:n] {
result[i] = int(x)
}
}
}
return
}
// FindAllIndex returns a sorted list of non-overlapping matches of the
// regular expression r, where a match is a pair of indices specifying
// the matched slice of x.Bytes(). If n < 0, all matches are returned
// in successive order. Otherwise, at most n matches are returned and
// they may not be successive. The result is nil if there are no matches,
// or if n == 0.
//
func (x *Index) FindAllIndex(r *regexp.Regexp, n int) (result [][]int) {
// a non-empty literal prefix is used to determine possible
// match start indices with Lookup
prefix, complete := r.LiteralPrefix()
lit := []byte(prefix)
// worst-case scenario: no literal prefix
if prefix == "" {
return r.FindAllIndex(x.data, n)
}
// if regexp is a literal just use Lookup and convert its
// result into match pairs
if complete {
// Lookup returns indices that may belong to overlapping matches.
// After eliminating them, we may end up with fewer than n matches.
// If we don't have enough at the end, redo the search with an
// increased value n1, but only if Lookup returned all the requested
// indices in the first place (if it returned fewer than that then
// there cannot be more).
for n1 := n; ; n1 += 2 * (n - len(result)) /* overflow ok */ {
indices := x.Lookup(lit, n1)
if len(indices) == 0 {
return
}
sort.Ints(indices)
pairs := make([]int, 2*len(indices))
result = make([][]int, len(indices))
count := 0
prev := 0
for _, i := range indices {
if count == n {
break
}
// ignore indices leading to overlapping matches
if prev <= i {
j := 2 * count
pairs[j+0] = i
pairs[j+1] = i + len(lit)
result[count] = pairs[j : j+2]
count++
prev = i + len(lit)
}
}
result = result[0:count]
if len(result) >= n || len(indices) != n1 {
// found all matches or there's no chance to find more
// (n and n1 can be negative)
break
}
}
if len(result) == 0 {
result = nil
}
return
}
// regexp has a non-empty literal prefix; Lookup(lit) computes
// the indices of possible complete matches; use these as starting
// points for anchored searches
// (regexp "^" matches beginning of input, not beginning of line)
r = regexp.MustCompile("^" + r.String()) // compiles because r compiled
// same comment about Lookup applies here as in the loop above
for n1 := n; ; n1 += 2 * (n - len(result)) /* overflow ok */ {
indices := x.Lookup(lit, n1)
if len(indices) == 0 {
return
}
sort.Ints(indices)
result = result[0:0]
prev := 0
for _, i := range indices {
if len(result) == n {
break
}
m := r.FindIndex(x.data[i:]) // anchored search - will not run off
// ignore indices leading to overlapping matches
if m != nil && prev <= i {
m[0] = i // correct m
m[1] += i
result = append(result, m)
prev = m[1]
}
}
if len(result) >= n || len(indices) != n1 {
// found all matches or there's no chance to find more
// (n and n1 can be negative)
break
}
}
if len(result) == 0 {
result = nil
}
return
}